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Bull. Math. Soc. Sci. Math. Roumanie Tome 53(101) No. 1, 2010, 11–24 Dense Elements and Classes of Residuated Lattices by Claudia Mureşan Abstract In this paper we study the dense elements and the radical of a residuated lattice, residuated lattices with lifting Boolean center, simple, local, semilocal and quasi-local residuated lattices. BL-algebras have lifting Boolean center; moreover, Glivenko residuated lattices which fulfill the equation (¬ a → ¬ b) → ¬ b = (¬ b → ¬ a) → ¬ a have lifting Boolean center. Key Words: Residuated lattices, maximal filters, dense elements, lifting Boolean center. 2010 Mathematics Subject Classification: Primary 06F35, Secondary 03G10. 1 Introduction In this paper we study properties of residuated lattices related to the dense elements, the radical, the lifting Boolean center, as well as several classes of residuated lattices. In Section 2 of the article we recall some definitions and facts about residuated lattices that we use in the sequel: rules of calculus, definitions of several classes of residuated lattices, definitions of the regular elements, the Boolean center, the dense elements and the radical of a residuated lattice, definitions of filters and spectral topologies and first properties of the defined notions. In Section 3 we study the dense elements and the radical of a residuated lattice. We make this study for arbitrary residuated lattices, as well as for certain classes of residuated lattices. In Section 4 we study the property of lifting Boolean center for residuated lattices and indicate certain classes of residuated lattices which have lifting Boolean center. In Section 5 we study local, semilocal and simple residuated lattices and we define and study quasi-local residuated lattices. We also show the relations between these classes of residuated lattices. 12 2 Claudia Mureşan Preliminaries A (commutative) residuated lattice is an algebraic structure (A, ∨, ∧, ⊙, →, 0, 1), with the first 4 operations binary and the last two constant, such that (A, ∨, ∧, 0, 1) is a bounded lattice, (A, ⊙, 1) is a commutative monoid and the following property, called residuation, is satisfied: for all a, b, c ∈ A, a ≤ b → c ⇔ a ⊙ b ≤ c, where ≤ is the partial order of the lattice (A, ∨, ∧, 0, 1). In the following, unless mentioned otherwise, let A be a residuated lattice. We define two additional operations on A: for all a ∈ A, we denote ¬ a = a → 0, and, for all a, b ∈ A, we denote a ↔ b = (a → b) ∧ (b → a). Let a ∈ A and n ∈ IN∗ . We shall denote by an the following element of A: a ⊙ . . . ⊙ a. We also denote a0 = 1. | {z } n of a Let a ∈ A. The order of a, in symbols ord(a), is the smallest n ∈ IN∗ such that an = 0. If no such n exists, then ord(a) = ∞. Lemma 2.1. [15] Let a, b, c, d ∈ A. Then: (i) a ≤ b iff a → b = 1; (ii) a ≤ ¬ ¬ a; (iii) ¬ ¬ ¬ a = ¬ a; (iv) ¬ 0 = 1, ¬ 1 = 0; (v) if a ≤ b and c ≤ d then a ⊙ c ≤ b ⊙ d. An element a of A is said to be regular iff ¬ ¬ a = a. The set of all regular elements of A is denoted Reg(A). A is said to be involutive iff it verifies: for all a ∈ A, ¬ ¬ a = a, that is: Reg(A) = A. An MTL-algebra is a residuated lattice A that satisfies the preliniarity equation: for all a, b ∈ A, (a → b) ∨ (b → a) = 1. An involutive MTL-algebra is called an IMTL-algebra. A BL-algebra is an MTL-algebra A that satisfies the divisibility equation: for all a, b ∈ A, a ∧ b = a ⊙ (a → b). An MV-algebra is an algebra (A, ⊕, ¬ , 0) with one binary operation ⊕, one unary operation ¬ and one constant 0 such that: (A, ⊕, 0) is a commutative monoid and, for all a, b ∈ A, ¬ ¬ a = a, a⊕¬ 0 = ¬ 0, ¬ (¬ a⊕b)⊕b = ¬ (¬ b⊕a)⊕a. If A is an MV-algebra, then the binary operations ⊙, ∧, ∨, → and the constant 1 are defined by the following relations: for all a, b ∈ A, a ⊙ b = ¬ (¬ a ⊕ ¬ b), a ∧ b = (a ⊕ ¬ b) ⊙ b , a ∨ b = (a ⊙ ¬ b) ⊕ b, a → b = ¬ a ⊕ b, 1 = ¬ 0. According to [15, Theorem 3.2, page 99], MV-algebras are exactly the involutive BL-algebras. For a detailed exposition of MV-algebras see [1]. Again, in what follows, unless mentioned otherwise, let A be a residuated lattice. We denote by B(A) the Boolean center of A, that is the set of all complemented elements of the lattice (A, ∨, ∧, 0, 1). By [15, Lemma 1.12], the complements of the elements in the Boolean center of a residuated lattice are unique. For any element e from the Boolean center of a residuated lattice, we denote by Dense Elements and Classes of Residuated Lattices 13 e′ its complement. By [15, Lemma 1.13], any element e from the Boolean center of a residuated lattice satisfies: e′ = ¬ e. Proposition 2.2. [15, Proposition 1.17, page 15] For any e ∈ B(A), we have: e ⊙ e = e and e = ¬ ¬ e. Proposition 2.3. [15, Proposition 1.16, page 14] e ∈ B(A) iff e ∨ ¬ e = 1. By [15, Corollary 1.15], the Boolean center of A, with the operations induced by those of A, is a Boolean algebra. Let A1 , A2 be residuated lattices and f : A1 → A2 a morphism of residuated lattices. We denote by B(f ) : B(A1 ) → B(A2 ) the restriction of f to B(A1 ). It is known and immediate that B(f ) is well defined and it is a morphism of Boolean algebras, hence B is a covariant functor between the category of residuated lattices and the category of Boolean algebras. A nonempty subset F of A is called a filter of A iff it satisfies the following conditions: (i) for all a, b ∈ F , a ⊙ b ∈ F ; (ii) for all a ∈ F and all b ∈ A, if a ≤ b then b ∈ F . The set of all filters of A is denoted F(A). A filter F of A is said to be proper iff F 6= A. A subset F of A is called a deductive system of A iff it satisfies the following conditions: (i) 1 ∈ F ; (ii) for all a, b ∈ A, if a, a → b ∈ F then b ∈ F . By [15, Remark 1.11, page 19], a nonempty subset F of A is a filter iff it is a deductive system. A proper filter P of A is called a prime filter iff, for all a, b ∈ A, if a ∨ b ∈ P , then a ∈ P or b ∈ P . The set of all prime filters of A is called the (prime) spectrum of A and is denoted Spec(A). For any X ⊆ A, we shall denote S(X) = {P ∈ Spec(A)|X ⊆ / P }. For any a ∈ A, S({a}) will be denoted S(a). The family {S(X)|X ⊆ A} is a topology on Spec(A), having the basis {S(a)|a ∈ A} ([14, Proposition 2.1]). The family {S(X)|X ⊆ A} is called the Stone topology of A. A filter M of A is called a maximal filter iff it is a maximal element of the set of all proper filters of A. The set of all maximal filters of A is called the maximal spectrum of A and is denoted Max(A). For any X ⊆ A, we shall denote SMax (X) = {M ∈ Max(A)|X ⊆ / M }. For any a ∈ A, SMax ({a}) will be denoted SMax (a). It is a known fact that any maximal filter of a residuated lattice is a prime filter. It follows that the family {SMax (X)|X ⊆ A} is a topology on Max(A), having the basis {SMax (a)|a ∈ A}. This is the topology induced on Max(A) by the Stone topology. Let F be a filter of A. For all a, b ∈ A, we denote a ≡ b(mod F ) and say that a and b are congruent modulo F iff a ↔ b ∈ F . ≡ (mod F ) is a congruence relation on A. The quotient residuated lattice with respect to the congruence 14 Claudia Mureşan relation ≡ (mod F ) is denoted A/F and its elements are denoted a/F , a ∈ A. A consequence of Lemma 2.1, (i), is that, for all a, b ∈ A, if a ≤ b, then a/F ≤ b/F . 0, 1 ∈ Reg(A). By [3], if a, b ∈ A, then: ¬ ¬ (¬ ¬ a → ¬ ¬ b) = ¬ ¬ a → ¬ ¬ b. It follows that Reg(A) is closed with respect to → (because, by the above, for all a, b ∈ Reg(A), a → b = ¬ ¬ (a → b), hence a → b ∈ Reg(A)). We define on Reg(A) the following operations: for all a, b ∈ Reg(A), a ⊙∗ b = ¬ ¬ (a ⊙ b), a ∨∗ b = ¬ ¬ (a ∨ b) and a ∧∗ b = ¬ ¬ (a ∧ b). We will always refer to the operations above when studying the algebraic structure of Reg(A). A is said to be Glivenko iff it satisfies: for all a ∈ A, ¬ ¬ (¬ ¬ a → a) = 1. In the case of Glivenko MTL-algebras, the operations ∨∗ and ∧∗ coincide with ∨ and ∧, respectively ([4]). Proposition 2.4. [4, Theorem 2.1, page 163] The following are equivalent: (i) A is Glivenko; (ii) (Reg(A), ∨∗ , ∧∗ , ⊙∗ , →, 0, 1) is an involutive residuated lattice and ¬ ¬ : A → Reg(A) : a → ¬ ¬ a is a surjective morphism of residuated lattices. Note that Reg(A) = ¬ A (trivial). Proposition 2.5. [3, Lemma 2.4, (2), page 116] Let A be a Glivenko residuated lattice. Then Reg(A) is an MV-algebra (with the operation ⊕ defined by: for all a, b ∈ Reg(A), ¬ a ⊕ ¬ b = ¬ (a ⊙∗ b)) iff A satisfies the following equation: for all a, b ∈ A, (¬ a → ¬ b) → ¬ b = (¬ b → ¬ a) → ¬ a. Proposition 2.6. Let A be a Glivenko MTL-algebra. B(Reg(A)). Then B(A) = Proof: Obviously, B(Reg(A)) ⊆ B(A). For the converse set inclusion, let us consider an element e ∈ B(A). By Propositions 2.2 and 2.4, e = ¬ ¬ e ∈ B(A) ∩ Reg(A) and ¬ e ∈ Reg(A) = ¬ A. These two properties imply that e ∈ B(Reg(A)). An element a of A is said to be dense iff ¬ a = 0. We denote by Ds(A) the set of the dense elements of A. The intersection of all maximal filters of A is called the radical of A and is denoted Rad(A). Ds(A) is a filter of A and Ds(A) ⊆ Rad(A) ([8], [13], [15, Theorem 1.61]). Proposition 2.7. [3, Theorem 3.4, page 117] Let A be a Glivenko residuated lattice and θ : A/Ds(A) → Reg(A), for all a ∈ A, θ(a/Ds(A)) = ¬ ¬ a. Then θ is an isomorphism of residuated lattices and the following diagram is commutative: A pA Z Z ¬¬ Z A/Ds(A) θ ? ~ Z Reg(A) Dense Elements and Classes of Residuated Lattices 15 where, for all a ∈ A, pA (a) = a/Ds(A). Proposition 2.8. [3, Lemma 3.3, page 117] Let A be a residuated lattice. Then the following are equivalent: (i) A/Ds(A) is involutive; (ii) A is Glivenko. 3 Dense Elements and the Radical of a Residuated Lattice In this section we study the set of the dense elements and the radical of an arbitrary residuated lattice, as well as those of certain classes of residuated lattices. Proposition 3.1. Let A be a residuated lattice. Then: (i) Rad(A/Ds(A)) = Rad(A)/Ds(A); (ii) Max(A) and Max(A/Ds(A)) are homeomorphic topological spaces. Proof: (i) It is easily seen that Max(A/Ds(A)) = {N/Ds(A)|N ∈ Max(A)}, thus \ Rad(A/Ds(A)) = N/Ds(A) = N ∈Max(A) \ N ∈Max(A) N /Ds(A) = Rad(A)/Ds(A). (ii) Let us define h : Max(A) → Max(A/Ds(A)), for all N ∈ Max(A), h(N ) = N/Ds(A). By the above, this function is well defined and surjective. The injectivity of h easily follows by the immediate fact that, for any M ∈ Max(A) and any a ∈ A, a/Ds(A) ∈ M/Ds(A) iff a ∈ M . It remains to prove that h is continuous and open. Let b ∈ A. By using the above, we get: SMax (b/Ds(A)) = {N/Ds(A)|N ∈ Max(A), b/Ds(A) ∈ / N/Ds(A)} = {N/Ds(A)|N ∈ Max(A), b ∈ / N } = {N/Ds(A)|N ∈ SMax (b)} = {h(N )|N ∈ SMax (b)} = h(SMax (b)). So h is open. This and the injectivity of h prove that h−1 (SMax (b/Ds(A))) = SMax (b). So h is continuous. Therefore h is a homeomorphism. In [10], it is proven that, for any residuated lattice A and any filter F of A such that F ⊆ Ds(A), we have Ds(A/F ) = (Ds(A))/F . The example below shows that this is not the case for any filter. Example 3.2. There exist residuated lattices A and filters F of A such that Ds(A/F ) 6= (Ds(A))/F , and we give here one such example. Let us consider the following residuated lattice, taken from [11, Section 15.2.2]: A = {0, a, b, c, d, 1}, with the residuated lattice structure presented below: 16 Claudia Mureşan r c ¡ @ 1 r ¡@ @r d ¡ r @¡ b ra r 0 → 0 a b c d 1 0 1 d a 0 a 0 a 1 1 a a a a b 1 1 1 d c b c 1 1 1 1 c c d 1 1 1 d 1 d 1 1 1 1 1 1 1 ⊙ 0 a b c d 1 0 0 0 0 0 0 0 a 0 0 0 a 0 a b 0 0 b b b b c 0 a b c b c d 0 0 b b d d 1 0 a b c d 1 Ds(A) = {c, 1}. Let F = {d, 1}. Ds(A)/F = {c/F, 1/F }. For example, b/F ∈ Ds(A/F ) (since ¬ b/F = a/F = 0/F ) and b/F ∈ / Ds(A)/F (since b/F 6= c/F and b/F 6= 1/F ). Proposition 3.3. Let A be a Glivenko residuated lattice and a ∈ A. Then: a ∈ Rad(A) iff ¬ ¬ a ∈ Rad(A). Proof: By using in turn Proposition 3.1, (i), Proposition 2.8 and again Proposition 3.1, (i), we get: a ∈ Rad(A) iff a/Ds(A) ∈ Rad(A)/Ds(A) iff ¬ ¬ a/Ds(A) ∈ Rad(A)/Ds(A) iff ¬ ¬ a ∈ Rad(A). Remark 3.4. Notice that, according to Proposition 3.1, (i), in Proposition 3.3 it was not necessary for A to be Glivenko; instead, it was sufficient for A/Ds(A) to satisfy the equivalence: x ∈ Rad(A/Ds(A)) iff ¬ ¬ x ∈ Rad(A/Ds(A)). Proposition 3.5. Let A be a Glivenko residuated lattice. Rad(Reg(A)) = Rad(A) ∩ Reg(A). Then: Proof: Let us first prove that ¬ ¬ (Rad(A)) = Rad(A) ∩ Reg(A). For all a ∈ A, a ∈ Rad(A) ∩ Reg(A) iff a ∈ Rad(A) and a = ¬ ¬ a, which implies a ∈ ¬ ¬ (Rad(A)). Let a ∈ ¬ ¬ (Rad(A)), hence a = ¬ ¬ b, with b ∈ Rad(A), hence, by Proposition 3.3, ¬ ¬ b ∈ Rad(A), so a ∈ Rad(A). But ¬ ¬ (Rad(A)) ⊆ ¬ ¬ A = Reg(A), by Proposition 2.4. So a ∈ Rad(A) ∩ Reg(A). Hence the desired set equality. Propositions 2.7 and 3.1, (i), and the observation in the previous paragraph show that: 17 Dense Elements and Classes of Residuated Lattices Rad(Reg(A)) = Rad(θ(A/Ds(A))) = θ(Rad(A/Ds(A))) = θ(Rad(A)/Ds(A)) = θ(pA (Rad(A))) = ¬ ¬ (Rad(A)) = Rad(A) ∩ Reg(A) . Proposition 3.6. Let A be a Glivenko residuated lattice. Then: A/Ds(A) is an MV-algebra iff A satisfies the equation: (¬ a → ¬ b) → ¬ b = (¬ b → ¬ a) → ¬ a. As a consequence, for any BL-algebra A, A/Ds(A) is an MV-algebra. Proof: By Propositions 2.7 and 2.5. In the following we will give an example of an MTL-algebra A such that A/Ds(A) is not an MV-algebra, actually not even a BL-algebra. An MTL-algebra A that is not a BL-algebra and in which Ds(A) = {1} will provide us with the desired example. Example 3.7. We are using an example in [11, Section 14.1.2]. Let A = {0, a, b, c, d, 1}, with 0 < a < b < c < d < 1 and the following operations: → 0 a b c d 1 0 1 d c b a 0 a 1 1 c b a a b 1 1 1 c b b c 1 1 1 1 c c d 1 1 1 1 1 d 1 1 1 1 1 1 1 ⊙ 0 a b c d 1 0 0 0 0 0 0 0 a 0 0 0 0 0 a b 0 0 0 0 b b c 0 0 0 b c c d 0 0 b c d d 1 0 a b c d 1 With these operations, A becomes an MTL-algebra (even an IMTL-algebra) that is not a BL-algebra. Indeed, b ∧ a = a 6= 0 = b ⊙ (b → a), so A does not satisfy the divisibility equation. As one can see, Ds(A) = {1}, so A/Ds(A) ∼ = A, which is not a BL-algebra. 4 Lifting Boolean Center In this section we collect several results about residuated lattices with lifting Boolean center. In what follows, we recall the definition of the residuated lattices with lifting Boolean center, that we gave in [10]. In the following, unless mentioned otherwise, let A be a residuated lattice and let us consider the commutative diagram below, where, for all a ∈ A, pA (a) = a/Ds(A), rA (a) = a/Rad(A) (the canonical surjections) and φA (a/Ds(A)) = a/Rad(A). Since Ds(A) ⊆ Rad(A), we have that φA is well defined and it is a morphism of residuated lattices. 18 Claudia Mureşan A pA Z Z rA Z A/Ds(A) φA ? ~ Z A/Rad(A) As we have seen in Section 2, it follows that we have the commutative diagram below in the category of Boolean algebras. B(A) B(pA )- Z B(rA )ZZ B(A/Ds(A)) B(φA ) ~ ? Z B(A/Rad(A)) Lemma 4.1. [10] B(pA ) and B(rA ) are injective. Definition 4.2. A has lifting Boolean center iff B(rA ) is surjective (and hence a Boolean isomorphism). Proposition 4.3. If A is Glivenko, then: A has lifting Boolean center iff B(φA ) is surjective. Proof: The direct implication results by Definition 4.2. If A is Glivenko, then in the following commutative diagram θ is an isomorphism of residuated lattices, as we have seen in Proposition 2.7: A pA Z Z ¬¬ Z A/Ds(A) θ ~ ? Z Reg(A) In the category of Boolean algebras we have the following commutative diagram, in which B(θ) is a Boolean isomorphism by the above and B(¬ ¬ ) is a Boolean isomorphism by Proposition 2.2. This holds the proof of the converse implication. B(rA ) B(A/Rad(A)) B(A) P PP B(p ) 6 PP A B(¬ ¬ ) B(φA ) PP ? P q P B(A/Ds(A)) B(Reg(A)) ¾ B(θ) Dense Elements and Classes of Residuated Lattices 19 Proposition 4.4. [10] A/Ds(A) has lifting Boolean center iff B(φA ) is a Boolean isomorphism. Proposition 4.5. Let A be a Glivenko residuated lattice. Then: if A/Ds(A) has lifting Boolean center then A has lifting Boolean center. Proof: By Propositions 4.4 and 4.3. Proposition 4.6. [7, Proposition 5] Any MV-algebra has lifting Boolean center. Corollary 4.7. Any BL-algebra has lifting Boolean center. Proof: Let A be a BL-algebra. Then: A is Glivenko ([4]) and, by Propositions 3.6, 4.6 and 4.5, A/Ds(A) is an MV-algebra, so A/Ds(A) has lifting Boolean center, hence A has lifting Boolean center. Corollary 4.8. Any Glivenko residuated lattice A that satisfies the following equation: for all a, b ∈ A, (¬ a → ¬ b) → ¬ b = (¬ b → ¬ a) → ¬ a, has lifting Boolean center. Proof: By Propositions 3.6, 4.6 and 4.5. See [10] for an example of a residuated lattice that does not have lifting Boolean center. 5 Simple and Quasi-local Residuated Lattices In this section we study the classes of local, semilocal, simple and quasilocal residuated lattices, as well as the relations between these classes. Semilocal and quasi-local residuated lattices are more general concepts than local residuated lattices. Quasi-local residuated lattices extend quasi-local MV-algebras and quasi-local BL-algebras (structures that characterize weak Boolean products of local MV-algebras, respectively weak Boolean products of local BL-algebras) (by [6]). We conjecture that this result remains valid for a much larger class of residuated lattices; the characterization of this class is still an open problem. Definition 5.1. A residuated lattice is said to be local iff it has exactly one maximal filter. Proposition 5.2. If A is a local residuated lattice, then the unique maximal filter of A is D(A) = {a ∈ A|ord(a) = ∞}, so Rad(A) = D(A). 20 Claudia Mureşan Proof: This is part of [5, Theorem 4.3]. It is known that simple residuated lattices are characterized by the following result. Proposition 5.3. A residuated lattice A is simple iff, for every a ∈ A, a 6= 1 ⇒ ord(a) < ∞. Proposition 5.4. Any simple residuated lattice is local. Proof: It is immediate that the only filters of a simple residuated lattice A are {1} and A, so the only maximal filter is {1}. Proposition 5.5. [15, Theorem 1.60, page 35] Let A be a residuated lattice and M a proper filter of A. Then the following are equivalent: (i) A/M is a simple residuated lattice; (ii) M is a maximal filter. Definition 5.6. A residuated lattice is said to be semilocal iff it has only a finite number of maximal filters. It is obvious that any finite residuated lattice is semilocal and any local residuated lattice is semilocal. Proposition 5.7. For any residuated lattice A, |Max(A)| = |Max(A/Rad(A))|. Hence, A is semilocal iff A/Rad(A) is semilocal, and A is local iff A/Rad(A) is local. Proof: In a manner similar to the proof of Proposition 3.1, (ii), one can show that there is a bijection between Max(A) and Max(A/Rad(A)). Following the analogous definitions for BL-algebras from [6], we define the quasi-local residuated lattices and the primary and quasi-primary filters of a residuated lattice. Definition 5.8. A proper filter F of a residuated lattice A is called primary iff, for all a, b ∈ A, ¬ (a ⊙ b) ∈ F implies that there exists n ∈ IN∗ such that ¬ an ∈ F or ¬ bn ∈ F . Definition 5.9. A residuated lattice A is called quasi-local iff, for any a ∈ A, there exist e ∈ B(A) and n ∈ IN∗ such that an ⊙ e = 0 and (¬ a)n ⊙ (¬ e) = 0. Dense Elements and Classes of Residuated Lattices 21 Definition 5.10. A proper filter F of a residuated lattice A is called quasiprimary iff, for all a, b ∈ A, ¬ (a ⊙ b) ∈ F implies that there exist u ∈ A and n ∈ IN∗ such that u ∨ ¬ u ∈ B(A), ¬ (an ⊙ u) ∈ F and ¬ (bn ⊙ ¬ u) ∈ F . The proposition below, in its variant for BL-algebras, is [6, Proposition 4.10]; its proof is also valid for residuated lattices. Proposition 5.11. Any primary filter of a residuated lattice is quasi-primary. Proposition 5.12. [5, Corollary 4.4] If A is a local residuated lattice, then: for any a ∈ A, ord(a) < ∞ or ord(¬ a) < ∞. Proposition 5.13. Any local residuated lattice is quasi-local. Proof: Same as the proof of the first implication from [6, Proposition 4.9] (see Proposition 5.12). Proposition 5.14. If A is a local residuated lattice, then B(A) = {0, 1}. Proof: Same as the proof of [6, Proposition 4.4] (see Proposition 5.12). Proposition 5.15. Let A be a quasi-local residuated lattice and F a filter of A. Then A/F is quasi-local. Proof: Obviously, it is sufficient to prove that B(A/F ) ⊇ B(A)/F . By Proposition 2.3, B(A/F ) = {e/F |e ∈ A, e ∨ ¬ e ∈ F } ⊇ {e/F |e ∈ A, e ∨ ¬ e = 1} = {e/F |e ∈ B(A)} = B(A)/F . Proposition 5.16. Let A be a residuated lattice and let us consider the following properties: (i) A is quasi-local; (ii) A/Ds(A) is quasi-local. Then: (I) (i) implies (ii); (II) if A is Glivenko and it satisfies the equation: for all a, b ∈ A, (¬ a → ¬ b) → ¬ b = (¬ b → ¬ a) → ¬ a, then (ii) implies (i). Proof: (I) By Proposition 5.15. (II) Assume that A/Ds(A) is quasi-local and that A is Glivenko and it satisfies the equation: for all a, b ∈ A, (¬ a → ¬ b) → ¬ b = (¬ b → ¬ a) → ¬ a. This last condition is equivalent to the fact that Reg(A) is an MV-algebra (see Proposition 2.5). The fact that A is Glivenko implies that A/Ds(A) and Reg(A) are isomorphic residuated lattices (see Proposition 2.7), hence Reg(A) is quasi-local. Let a ∈ A. By Lemma 2.1, (iii), ¬ a ∈ Reg(A), so there exist e ∈ B(Reg(A)) and 22 Claudia Mureşan n ∈ IN∗ such that (¬ a)n ⊙ e = 0 and (¬ ¬ a)n ⊙ (¬ e) = 0. This last equality and Lemma 2.1, (ii) and (v), ensure us that an ⊙(¬ e) = 0. The fact that (¬ a)n ⊙e = 0 and Proposition 2.2 show that (¬ a)n ⊙ (¬ ¬ e) = 0. Since e ∈ B(A), we have that ¬ e = e′ ∈ B(A). So A is quasi-local. Let us remark that, in Proposition 5.16, (ii) does not imply (i). The following example of residuated lattice from [11, Section 16] proves this property: Example 5.17. Let A = {0, a, b, c, d, e, 1}, with the residuated lattice structure shown below: 1r b r¡ a r @ → 0 a b c d e 1 0 1 d d b b 0 0 a 1 1 e b b b a b 1 1 1 b b b b c 1 d d 1 e d c d 1 d d 1 1 d d e 1 1 1 1 1 1 e 1 1 1 1 1 1 1 1 re ¡@ @r¡ 0 @r d ¡ rc ⊙ 0 a b c d e 1 0 0 0 0 0 0 0 0 a 0 a a 0 0 a a b 0 a a 0 0 a b c 0 0 0 c c c c d 0 0 0 c c c d e 0 a a c c e e 1 0 a b c d e 1 One can see that B(A) = {0, 1}. It is easy to check that A is not quasi-local. Just take a instead of a in Definition 5.9. Ds(A) = {e, 1}. As the table of the operation ↔ shows, A/Ds(A) = {0/Ds(A), a/Ds(A) = b/Ds(A), c/Ds(A) = d/Ds(A), e/Ds(A) = 1/Ds (A)}. Using Lemma 2.1, (i), we get the following lattice structure for A/Ds(A): 1/Ds(A) r ¡@ r @r c/Ds(A) a/Ds(A) ¡ @ ¡ @r¡ 0/Ds(A) Hence B(A/Ds(A)) = A/Ds(A). It is easy to verify that A/Ds(A) is quasilocal. Dense Elements and Classes of Residuated Lattices 6 23 Acknowledgements I thank Professor George Georgescu for offering me this research theme and for numerous suggestions concerning the tackling of these mathematical problems. I also thank the anonymous reviewer for his or her very helpful comments and suggestions. References [1] R. Cignoli, I.M.L. D’Ottaviano, D. Mundici, Algebraic Foundations of Many-valued Reasoning, Trends in Logic-Studia Logica Library 7, Kluwer Academic Publishers, Dordrecht (2000). [2] R. Cignoli, F. Esteva, L. Godo, A. Torrens, Basic Fuzzy Logic is the Logic of Continuous t-norms and Their Residua, Soft Computing 4 (2000), 106-112. [3] R. Cignoli, A. Torrens, Glivenko-like Theorems in Natural Expansions of BCK-Logic, Math. Log. Quart. 50, No. 2 (2004), 111-125. [4] R. Cignoli, A. Torrens, Free Algebras in Varieties of Glivenko MTLalgebras Satisfying the Equation 2(x2 ) = (2x)2 , Studia Logica 83 (2006), 157-181. [5] L. C. Ciungu, Local Pseudo-BCK Algebras with Pseudo-product, submitted. [6] A. Di Nola, G. Georgescu, L. Leuştean, Boolean Products of BLalgebras, J. Math. Anal. Appl. 251, No. 1 (2000), 106-131. [7] A. Filipoiu, G. Georgescu, A. Lettieri, Maximal MV-algebras, Mathware Soft Comput. 4, No. 1 (1997), 53-62. [8] H. Freytes, Injectives in Residuated Algebras, Algebra Universalis 51 (2004), 373-393. [9] G. Georgescu, L. Leuştean, Some Classes of Pseudo-BL Algebras, J. Aust. Math. Soc. 73, No. 1 (2002), 127-153. [10] G. Georgescu. L. Leuştean, C. Mureşan, Maximal Residuated Lattices with Lifting Boolean Center, submitted. [11] A. Iorgulescu, Classes of BCK Algebras-Part IV, Preprint Series of the Institute of Mathematics of the Romanian Academy, preprint No. 4 (2004), 1-37. [12] A. Iorgulescu, Algebras of Logic as BCK Algebras, ASE Publishing House, Bucharest (2008). 24 Claudia Mureşan [13] T. Kowalski, H. Ono, Residuated Lattices: An Algebraic Glimpse at Logics without Contraction, manuscript. [14] C. Mureşan, Characterization of the Reticulation of a Residuated Lattice, to appear in Journal of Multiple-valued Logic and Soft Computing. [15] D. Piciu, Algebras of Fuzzy Logic, Universitaria Craiova Publishing House, Craiova (2007). [16] E. Turunen, S. Sessa, Local BL-algebras, Mult.-Valued Log. 6, No. 1-2 (2001), 229-249. Received: 05.01.2009. Revised: 14.10.2009. University of Bucharest, Faculty of Mathematics and Computer Science, Academiei 14, RO 010014, Bucharest, Romania E-mail: c.muresan @yahoo.com